Tensioning device for bag filters

ABSTRACT

For an inside to outside dust collector, a tensioning device for bag filters for connecting the upper end of a fabric sleeve filter to an overhead support. The device includes a modified double draw bar spring assembly having a conical spring therein interposed between the overhead support of the baghouse and the upper end of the bag filter. A retainer member engaging the large end of the conical spring receives therethrough the first and second draw bars to prevent binding of the spring assembly and to translate the conical spring force to uniform linear forces acting through the first and second draw bars to appropriately tension the filter sleeve and to permit controlled flexure during cycling from a filtering to a cleaning operation.

BACKGROUND AND SUMMARY OF THE INVENTION

This application is a continuation-in-part of our copending application Ser. No. 630,668, filed July 13, 1984 and entitled "Tensioning Device for Bag Filters" now abandoned.

This invention relates to industrial baghouses and, more particularly, to a tensioning device for connecting cylindrical bag filters to an overhead support.

Continuous emphasis on environmental quality has resulted in increasingly strenuous regulatory controls on industrial emissions. One technique which has proven highly effective in controlling air pollution has been separation of undesirable particulate matter from a gas stream by fabric filtration. Such filtration is carried out in dust collection apparatus known in the trade as a "baghouse" which operates on the same general principle as an ordinary household vacuum cleaner, except on a much larger scale. Basically, the baghouse is a sheet metal housing divided into two chambers, referred to as plenums, by a tube sheet. Disposed within openings in the tube sheet are fabric filters. A particulate laden gas stream induced by the action of a fan, blows into one chamber (dirty air plenum) wherein dust accumulates on the fabric filter as the gas passes through the fabric into the other plenum (clean air plenum) and out an exhaust. Although all baghouses are designed in accordance with the foregoing general principles, there are numerous operational and structural distinctions. The present invention relates to a baghouse wherein a plurality of cylindrical filter bags having closed upper ends are vertically suspended in the clean air plenum from a bag support framework. The lower ends of the bags are fixed to openings in a tube sheet or cell plate. Filtration of the process gas occurs from inside to outside of the bags (i.e., the dust collects on the inside surface of each bag). As a result, baghouses constructed in this manner are normally referred to as inside to outside bag collectors.

During continuous operation of the baghouse the bags must be periodically cleaned to remove the dust cake which accumulates within each filter sleeve. This may be done by interrupting the flow of the process gas carrying particulate matter and then causing reverse cleaning air to flow from the clean air plenum to the dirty air plenum. The reverse flow of cleaning air causes the dust cake to be dislodged and fall through the interior of the bag to the dirty air plenum for removal by an auger or similar means. In some baghouse installations, reverse air cleaning may also be supplemented with mechanical shaking of the filters.

The air cleaning process reverses the pressure drop the fabric filter normally experiences during filtering operation. In other words, the filter sleeve tends to collapse inwardly when being cleaned. This tendency is limited somewhat by circular support rings sewn to the outside of the bag at spaced intervals along its length.

Proper tensioning of the bags plays an important role in eliminating fabric collapse during the cleaning and filtering process. If the bags are stretched too tightly between the support framework and the cell plate, the bags do not collapse during cleaning, but they tend to wear out quickly. If, on the other hand, the bags are installed too loosely then the fabric between adjacent skeletal support rings collapses during cleaning and will not permit the dust cake to fall through the bag to the bottom of the dirty air plenum.

Even when a filter bag is properly installed and tensioned correctly, it is reasonable to expect the fabric to stretch with age and with repeated cyclings between the filtering and cleaning modes of operation. Thus, the bags must be periodically checked and the tension readjusted for each bag from time to time.

The installation and maintenance of filter bags of this genre has traditionally been a time consuming and costly operation. Accordingly, there has been a long felt need in this industry for improvements in filter bag assemblies and mounting techniques to alleviate the many installation and maintenance difficulties which have been encountered.

An earlier solution for properly tensioning filter bags is found in U.S. Pat. No. 4,364,758 of Clements et al issued Dec. 21, 1982 and entitled "Self Tensioning Cap for Bag Filters". This patent is incorporated herein by reference and is generally illustrative of the environment of the instant invention. In cited U.S. Pat. No. 4,364,758, the tensioning feature requires a rigid closure cap which closes the upper end of the fabric filter. Interiorly of the filter bag (i.e., below the cap itself) a tensioning spring is carried on a support rod. When the support rod is mounted on the bag support framework, the tensioning spring acts against the cap and pushes it upwardly relative to the end of the support rod to thus tension the bag. Adjustment may be achieved by supporting the retainer rod through one of a plurality of holes in the support rod by means of a removable pin which acts against the upper surface of the support framework. It is also contemplated in this earlier patent that the tensioning spring can be compressed between the closure cap and the support rod and captured by means of a removable pin. Thus, after installation, the capture pin may be removed to permit the spring to act on the cap and tension the bag.

Application of the foregoing prior art technique is limited, however, to specific baghouse configurations provided sufficient overhead room above the bag support framework to permit both the initial installation and subsequent adjustment of the tensioning assembly. Further, this earlier arrangement placed the flexing components of the tensioning device on the process gas side of the filtering operation which, in some process applications, subjected the flexing members to a rather corrosive environment.

Accordingly, a need remains in the industry for a broad application tensioning device to be employed in a greater range of baghouse configurations. The primary goal of this invention is to fulfill this need.

More specifically, a goal of the invention is to provide a filter bag tensioning device universally adaptable to various baghouse configurations without the need of structural changes within the baghouse.

Another object of the invention is to provide a tensioning device achieving the advantages of tensioning the filter bags in baghouses having highly limited access around the bag support framework.

An additional object of the invention is to provide a tensioning device of the character described and adapted to baghouse installations wherein limited distance is available between the end of the filter bag and the bag support framework.

Yet another object of the invention is to provide a tensioning device of the character described which may be utilized with filter sleeves having a wide range of end closure configurations.

A further object is to provide a tensioning device which will function with a broad range of configurations of the overhead framework within the baghouse.

Other and further objects of the invention, together with the features of novelty appurtenant thereto, will appear in the course of the following description.

DESCRIPTION OF THE DRAWINGS

In the accompanying drawings which form a part of the specification and are to be read in conjunction therewith and in which like reference numerals are used to indicate like parts in the various views:

FIG. 1 is a side elevational view of a tensioning device interconnecting the upper end of a filter sleeve with the overhead support framework of a baghouse illustrating a first embodiment of the invention;

FIG. 2 is a side elevational view taken 90° to the FIG. 1 view and with the retaining spring released to pull taut the fabric filter sleeve;

FIG. 3 is a side elevational view of a second embodiment of the invention;

FIG. 4 is a side elevational view taken 90° from the FIG. 3 view and with the retaining spring released to pull taut the fabric filter sleeve;

FIG. 5 is a top plan view of the spring tensioning device taken along line 5--5 of FIG. 4 in the direction of the arrows to better illustrate the details of construction;

FIG. 6 is a side elevational view of a third embodiment of the invention;

FIG. 7 is a side elevational view taken 90° from the view in FIG. 6;

FIG. 8 is a top plan view of the retainer washer of the spring assembly taken along line 8--8 of FIG. 7 in the direction of the arrows to better illustrate the details of construction; and

FIG. 9 is a schematic elevational view within a baghouse to illustrate the environment in which the invention is used.

DETAILED DESCRIPTION OF THE DRAWINGS

The various views of the various embodiments of the invention will be understood by those skilled in art to be located within the upper region of the clean air plenum of a baghouse. The overall environment in which the present invention is installed is schematically illustrated and described in U.S. Pat. No. 4,364,758, incorporated by reference, and particularly shown in FIG. 1 of said patent which is substantially reproduced in the drawings herein as FIG. 9.

Referring then to the environment of the invention, attention is first directed to the schematic illustration of FIG. 9. The baghouse basically comprises a sheet metal housing 20 equipped with an inlet duct 21 to the dirty air plenum 22 and an outlet duct 23 from the clean air plenum 24. Process gas is pulled through the baghouse by means of a fan (not shown).

Interiorly of the housing 20, the dirty and clean air plenums 22 and 24 are separated by a horizontal cell plate 25. A plurality of holes 25a penetrate the cell plate 25 and are integrally fitted with short cylindrical flanges extending upwardly.

In the upper region of the clean air plenum 24 is mounted a bag support framework 26 which, as shown in FIG. 2, is constructed of C-shaped channel members. The bag support framework can similarly be constructed of angle iron or flat iron and may be equipped with mechanical shaking apparatus as is known to be conventional in this art.

Mounted within the clean air plenum 24 are a plurality of filter assemblies. The assemblies include cylindrical fabric sleeve filters 27. The lower end of each sleeve filter 27 is fitted over the cylindrical flange of the cell plate 25 and secured thereto by a clamping band 28. At spaced intervals along the length of the filter sleeves 27 are sewn skeletal support rings 29 to prevent collapse of the bag during reverse air cleaning. At the upper end of the filter sleeve 27, the fabric filter is secured to a bag connection member such as end cap 31 which is suspendingly connected to the overhead framework 26 by a hanger assembly, such as rod 33. The present invention deals more particularly with the assembly for suspending and tensioning the filter bags from the overhead support.

Referring to the first embodiment of the invention shown in FIGS. 1 and 2, within the upper region of the clean air plenum is mounted a bag support framework which, as shown, may be constructed of angle iron members 100. The bag support framework can similarly be constructed of C-shaped channels, H beams, flat irons, and, in fact, most any structural element sufficient to form a sturdy framework for supporting a plurality of bags within the baghouse. The horizontal leg 100a of the angle iron support 100 includes an opening 100b therethrough used for connecting a filter bag to the framework. The bag support framework may additionally be equipped with mechanical shaking apparatus (not shown) as is known to be conventional in this art to assist in the cleaning operation.

Mounted within the clean air plenum are a plurality of filter assemblies, the upper end of one such filter assembly 102 is shown in FIGS. 1 and 2. The lower end of the filter sleeve 104 is securely fixed to a cell plate separating the dirty and clean air plenums. Particulate laden process gas may thus flow from the dirty air plenum, through the cell plate to the interior of the filter sleeve 104.

As illustrated in FIGS. 1 and 2, a spring tensioning assembly 110 is interposed in the connecting linkage between the top of the filter assembly 102 and the overhead support structure 100 characteristically found in a baghouse. Focusing first on the spring tensioning assembly 110 itself, there is included a conical spring 112 having a greater diameter end 113 and a progressively lesser diameter, opposite end 114. Contacting the greater diameter end 113 of the conical spring 112 is a retainer washer 116 which forms a first spring biasing surface. The retainer washer 116 is of the same form as illustrated in FIG. 5 and includes a central slot 117 therethrough. A support chain 118 extends centrally through the conical spring 112 and one terminal link 119 of the chain 118 passes through the slot 117 in the retainer washer 116 which receives a cross bolt or keeper link 120.

The support chain 118 passes upwardly from the retainer washer 116 centrally through the conical spring 112 and through the opening 100b in the overhead support 100a where it is secured by a hitch pin clip 122 passed through one link (i.e., link 124) of the chain 118.

Also extending centrally through the conical spring 112, on the outside of the support chain 118, is a draw bar 126. The draw bar 126 is in the form of a U-shaped member having legs 126a and 126b which pass upwardly through the slot 117 in the retainer washer 116 and which terminate in outwardly extending ears 126c and 126d which overlie the lesser diameter end 114 of the conical spring 112 to provide a second spring biasing surface. The bight end 126e of the draw bar 126 carries a chain or S-hook 128 connected to a hanger 129 which receives the fabric loop 105 of the filter sleeve 104 having a tapered upper end 106 well known to those in this industry.

In the pretensioned condition of the spring assembly 110 illustrated in FIG. 1, prior to completed installation of the filter assembly, the conical spring 112 is compressed between the first and second spring biasing surfaces provided respectively by the retainer washer 116 and the ears 126c and 126d of the draw bar 126. The conical spring 112 is captured in the foregoing position by a hitch pin clip 130 through one of the links of support chain 118 to retainingly engage the lesser diameter end 114 of the spring 112.

In operation, the lower end of the filter sleeve 104 is secured in a conventional manner to the cell plate in the bottom region of the baghouse. The upper end of the filter sleeve is connected to the spring tensioning assembly 110 as indicated with the conical spring 112 captured between the first and second spring biasing surfaces. The tag end of the support chain 118 is inserted through the opening 100b in the overhead support 100a and the clip 122 is installed through a link 124 of the chain to suspend the entire filter assembly 102 from the support structure in a pretensioned condition. The pin clip 130 is then removed from the chain 118 to release the conical spring 112. The spring 118 acts against the retainer washer 116 and the ears 126c and 126d of the draw bar 126 to provide opposing forces to spread apart the first and second spring biasing surfaces and, thus, to tension the filter sleeve 104 as appropriate to complete installation as illustrated in FIG. 2.

Referring to the second embodiment of the invention shown in FIGS. 3--5, within the upper region of the clean air plenum is mounted a bag support framework which, as shown, may be constructed of angle iron members 200. The horizontal leg 200a of the angle iron support 200 includes an opening 200b therethrough used for connecting a filter bag to the framework.

Mounted within the clean air plenum are a plurality of filter assemblies, the upper end of one such filter assembly 202 is shown in FIGS. 3 and 4. The lower end of the filter sleeve 204 is securely fixed to a cell plate separating the dirty and clean air plenums. Particulate laden process gas may thus flow from the dirty air plenum, through the cell plate to the interior of the filter sleeve 204.

As illustrated in FIGS. 3 and 4, a spring tensioning assembly 210 is interposed in the connecting linkage between the top of the filter assembly 202 and the overhead support structure 200 characteristically found in a baghouse. Focusing first on the spring tensioning assembly 210 itself, there is included a conical spring 212 having a greater diameter end 213 and a progressively lesser diameter, opposite end 214. Contacting the greater diameter end 213 of the conical spring 212 is a retainer washer 216 which forms a first spring biasing surface. The retainer washer 216 is illustrated in FIG. 5 and includes a central slot 217 therethrough. A support rod 238 having a plurality of lateral holes 238a therethrough extends centrally through the conical spring 212. One end of the rod 238 passes through the slot 217 in the retainer washer 216 and a rolled pin 220 is inserted in the outermost hole 238a of the rod 238 (FIG. 5).

Also extending centrally through the conical spring 212, on the outside of the support rod 238, is a draw bar 226. The draw bar 226 is in the form of a U-shaped member having legs 226a and 226b which pass through the slot 217 in the retainer washer 216 and which terminate in outwardly extending ears 226c and 226d which overlie the lesser diameter end 214 of the conical spring 212 to provide a second spring biasing surface. A support chain 218 extends upwardly from the bight 226e of the draw bar 226 and through the opening 200b in the overhead support 200a where it is secured by a hitch pin clip 222 passed through one link (i.e., link 224) of the chain 218.

The lower threaded end 238b of the support rod 238 is received by a female threaded coupler 205 fixed to a rigid end closure cap 206. Alternatively, the threaded end of the support rod may penetrate a hole in the cap 206 and be secured interiorly thereof by a nut or the like. The uppermost end of the filter sleeve is secured to the cap 206 in a manner commonly known in this art.

In the pretensioned condition of the spring assembly 210 illustrated in FIG. 3, prior to completed installation of the filter assembly, the conical spring 212 is compressed between the first and second spring biasing surfaces provided respectively by the retainer washer 216 and the ears 226c and 226d of the draw bar 226. The conical spring 212 is captured in the foregoing position by a hitch pin clip 230 through one of the holes 238a of support rod 238 to retainingly engage the lesser diameter end 214 of the spring 212.

In operation, the lower end of the filter sleeve 204 is secured in a conventional manner to the cell plate in the bottom region of the baghouse. The upper end of the filter sleeve is connected to the spring tensioning assembly 210 as indicated with the conical spring 212 captured between the first and second spring biasing surfaces. The tag end of the support chain 218 is inserted through the opening 200b in the overhead support 200a and the clip 222 is installed through a link 224 of the chain to suspend the entire filter assembly 202 from the support structure in a pretensioned condition. The pin clip 230 is then removed from the rod 238 to release the conical spring 212. The spring 212 acts against the retainer washer 216 and the ears 226c and 226d of the draw bar 226 to provide opposing forces to spread apart the first and second spring biasing surfaces and, thus, to tension the filter sleeve 204 as appropriate to complete installation as illustrated in FIG. 4.

The first and second embodiments of the invention as shown and described with reference to FIGS. 1-5 are utilized in connection with baghouse installations wherein it is desirable to pretension the spring assembly prior to installing the filter bag within the baghouse. Aspects of said embodiments are also useful with a conical spring used in a double draw bar arrangement, even though a conventional draw bar cannot be preloaded or captured in compression prior to installation. The conical spring finds beneficial application where the distance from bag to support is critically short because the conical spring can collapse to a shorter dimension than a conventional spring in order to permit proper tensioning of the filters.

Referring then to the third embodiment of the invention shown in FIGS. 6-8 there is generally shown a double draw bar spring arrangement modified to include a conical spring. Within the upper region of the clean air plenum is mounted a bag support framework which, as shown, may be constructed of angle iron members 300. The horizontal leg 300a of the angle iron support 300 includes an opening 300b therethrough used for connecting a filter bag to the framework.

Mounted within the clean air plenum are a plurality of filter assemblies, the upper end of one such filter assembly 302 is shown in FIGS. 6 & 7. The lower end of the filter sleeve 304 is securely fixed to a cell plate separating the dirty and clean air plenums. Particulate laden process gas may thus flow from the dirty air plenum, through the cell plate to the interior of the filter sleeve 304.

As illustrated in FIGS. 6 & 7, a spring tensioning assembly 310 is interposed in the connecting linkage between the top of the filter assembly 302 and the overhead support structure 300 characteristically found in a baghouse. Focusing first on the spring tensioning assembly 310 itself, there is included a conical spring 312 having a greater diameter end 313 and a progressively lesser diameter, opposite end 314. Contacting the greater diameter end 313 of the conical spring 312 is a retainer washer 316 which forms a first spring biasing surface. The retainer washer 316 is illustrated in FIG. 8 and includes a central opening therethrough 317 formed as pairs of opposed slots. One such pair of slots is designated by the reference numerals 317a & 317b and the other pair of slots is designated by the reference numerals 317c & 317d in FIG. 8. The slots 317a & 317b are oriented approximately ninety degrees from the slots 317c & 317d.

Extending centrally through the conical spring 312 is a first draw bar 326. The draw bar 326 is in the form of a U-shaped member having legs 326a and 326b which pass upwardly the opening 317 in the retainer washer 316 with the legs 326a & 326b being received respectively in the pair of slots 317a & 317b and which terminate in outwardly extending ears 326c and 326d which overlie the outer rim of the retainer washer 316. The bight end 326e of the draw bar 326 carries an S-hook 328 which is coupled to an eyebolt 329 or hook connected to the rigid, end closure cap 306. The cap 306 carries the filter sleeve 304 in a manner common and well known to the industry.

Also extending centrally through the conical spring 312, is a second draw bar 330. The draw bar 330 is in the form of a U-shaped member having legs 330a & 330b which pass through the opening 317 in the retainer washer 316 with the legs 330a & 330b being received respectively in the pair of slots 317c & 317d and which terminate in outwardly extending ears 330c and 330d which overlie the lower end 314 of the spring 312 to provide a second spring biasing surface. A support chain 318 extends upwardly from the bight 330e of the draw bar 330 and through the opening 300b in the overhead support 300a where it is secured by a hitch pin clip 322 passed through one link (i.e., link 324) of the chain 318 when the filter 304 is properly tensioned (FIG. 7).

The assembly described with respect to the third embodiment of the invention may be reversed from the orientation shown in the drawings (i.e., the large end 313 of the conical spring 312 may be positioned beneath the smaller end 314) without loss of benefit.

In operation, the lower end of the filter sleeve 304 is secured in a conventional manner to the cell plate in the bottom region of the baghouse. The upper end of the filter sleeve is connected to the spring tensioning assembly 310 as indicated with the conical spring 312 captured between the first and second spring biasing surfaces. The tag end of the support chain 318 is inserted through the opening 300b in the overhead support 300a and the clip 322 is installed through a link 324 of the chain 318 (FIG. 7) to suspend and tension the entire filter assembly 302 from the support structure 300. The spring 312 acts against the retainer washer 316 and the ears 330c and 330d of the second draw bar 330 to provide opposing forces to spread apart the first and second spring biasing surfaces and, thus, to tension the filter sleeve 304 as appropriate. The retainer washer 316 acts to separate and maintain proper orientation of the first and second draw bars 326 & 330 so they do not bind one another during the normal flexing of the filter bag. In addition, it should be noted that the retainer washer translates the spring force to uniformly opposed lineal forces, even though the spring 312 is conical, as a result of the arrangement of the pairs of slots 317a & 317b and 317c & 317d being spaced outwardly a common distance from the central longitudinal axis of the assembly 310 as illustrated in FIG. 8.

The foregoing embodiments represent broad application in the baghouse arts of the principles of this invention. A wide variety of connections may be utilized in supporting the spring assembly herein from the overhead support framework. Likewise, a wide variety of connections may be utilized for connecting the spring assembly to the filter itself. Any of the foregoing connections may have take-up adjustment for ease of installation. In addition, the various assemblies can be reversed depending upon the structural conditions encountered by baghouse maintenance personnel when installing the tensioning devices.

Heretofore, a need has existed for an external tensioning device for bag filters. Double draw bars have been utilized but were cumbersome in installation adjustments and could not be preloaded to provide an appropriate tensioning force. The instant invention achieves the goal of providing a preloaded, external tensioning device to appropriately tension bags in a wide variety of structural configurations where overhead room is limited or a limited space between the bag and support framework is indicated. With respect to the latter consideration, shortening of the bags is of course undesirable due to the reduction in filter cloth area. Even where the distance from bag to support is critically short, the preloaded spring assembly utilizing the conical spring which can collapse to a shorter dimension than a conventional spring will permit proper tensioning of the filters.

Similarly, where the feature of preloading is not required, this invention provides a unique means of utilizing a conical spring in a double draw bar assembly to eliminate binding or chafing of the components and to translate the conical spring load to uniformly opposed lineal forces.

From the foregoing it will be seen that this invention is one well adapted to attain all end and objects hereinabove set forth together with the other advantages which are obvious and which are inherent to the structure.

It will be understood that certain features and subcombinations are of utility and may be employed without reference to other features and subcombinations. This is contemplated by and is within the scope of the claims.

Since many possible embodiments may be made of the invention without departing from the scope thereof, it is to be understood that all matter herein set forth or shown in the accompanying drawings is to be interpreted as illustrative and not in a limiting sense. 

Having thus described our invention, we claim:
 1. In a dust collector having a bag support frame and a cell plate to which is connected one end of a fabric sleeve filter, a self tensioning bag device comprising:compressible conical spring means interconnected between said bag support frame and the other end of said fabric sleeve filter opposite said one end connected to said cell plate, said spring means having first and second open ends wherein said first end is larger in diameter that said second end and said spring means tapers uniformly from said first end to said second end; retainer means overlyingly connected to said first end of said conical spring means and having a central opening therethrough, said retainer means providing a first spring biasing surface; first draw bar means having outwardly extending ears engaging said retainer means and a U-shaped spring penetrating portion received within the central opening of said retainer means and received longitudinally through the length of said spring means to terminate in a bight end outwardly from said second end of said spring means; bag connecting means coupled to said bight end of said first draw bar and connected to said filter to suspendingly support said filter therefrom; second draw bar means having outwardly extending ears engaging said second end of said spring means to provide a second spring biasing surface, said second draw bar means including a U-shaped spring penetrating portion received longitudinally through the length of said spring means and received within the central opening of said retainer means to terminate in a bight end outwardly from said retainer means; adjustable frame support means connected to said bag support frame and to said bight end of said second draw bar means; and whereby said filter sleeve is suspended from said bag support frame and appropriately tensioned by said adjustable frame support means to permit said spring means to linearly act against said first and second spring biasing surfaces in opposing fashion.
 2. The dust collector as in claim 1 wherein said spring penetrating portion of said first draw bar means comprises a pair of spaced apart legs; said spring penetrating portion of said second draw bar means comprises a pair of spaced apart legs; and said opening in said retainer includes first and second pair of spaced apart slots wherein said second pair of slots are oriented substantially ninety degrees from said first pair; whereby said legs of said first draw bar are slidably received in said first pair of slots and said legs of said second draw bar are slidably received in said second pair of slots to prevent binding and to translate the spring force of said conical spring to opposed linear forces acting on said first and second draw bars.
 3. The dust collector as in claim 2 wherein said first and second pairs of slots are spaced radially outward a common distance from the center of said retainer to insure that lineal forces act through said first and second draw bar means.
 4. In a dust collector having a bag support frame and a cell plate to which is connected one end of a fabric sleeve filter, a self tensioning bag device comprising:compressible conical spring means interconnected between said bag support frame and the other end of said fabric sleeve filter opposite said one end connected to said cell plate, said spring means having first and second open ends wherein said first end is larger in diameter that said second end and said spring means tapers uniformly from said first end to said second end; retainer means overlyingly connected to said first end of said conical spring means and having a central opening therethrough, said retainer means providing a first spring biasing surface; first draw bar means having outwardly extending ears engaging said retainer means and a U-shaped spring penetrating portion received within the central opening of said retainer means and received longitudinally through the length of said spring means to terminate in a bight end outwardly from said second end of said spring means; adjustable frame support means connected to said bag support frame and to said bight end of said first draw bar means; second draw bar means having outwardly extending ears engaging said second end of said spring means to provide a second spring biasing surface, said second draw bar means including a U shaped spring penetrating portion received longitudinally through the length of said spring means and received within the central opening of said retainer means to terminate in a bight end outwardly from said retainer means; bag connecting means coupled to said bight end of said second draw bar and connected to said filter to suspendingly support said filter therefrom; and whereby said filter sleeve is suspended from said bag support frame and appropriately tensioned by said adjustable frame support means to permit said spring means to linearly act against said first and second spring biasing surfaces in opposing fashion.
 5. The dust collector as in claim 4 wherein said spring penetrating portion of said first draw bar means comprises a pair of spaced apart legs; said spring penetrating portion of said second draw bar means comprises a pair of spaced apart legs; and said opening in said retainer includes first and second pairs of spaced apart slots wherein said second pair of slots are oriented substantially ninety degrees from said first pair; whereby said legs of said first draw bar are slidably received in said first pair of slots and said legs of said second draw bar are slidably received in said second pair of slots to prevent binding and to translate the spring force of said conical spring to opposed linear forces acting on said first and second draw bars.
 6. The dust collector as in claim 5 wherein said first and second pair of slots are spaced radially outward a common distance from the center of said retainer to insure that lineal forces act through said first and second draw bar means. 